Journal
COMMUNICATIONS IN NONLINEAR SCIENCE AND NUMERICAL SIMULATION
Volume 108, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.cnsns.2021.106228
Keywords
Iterative parabolic equations; Kerr medium; Nonlinear Helmholtz equation; Exponential time differencing; Polynomial filtration; Pade approximation
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Funding
- POI FEB RAS Program Modeling of various-scale dynamical processes in the ocean, Russia [121021700341-2]
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In this study, a general approach to the numerical solution of iterative parabolic equations using the ETD pseudospectral method is developed. Pade-type iterative parabolic approximations are introduced to solve wave propagation problems more effectively.
Iterative parabolic equations (IPEs) were recently introduced as a promising tool for solving wave propagation problems in complex linear and non-linear media. In this study a general approach to the numerical solution of iterative parabolic equations on the basis of powerful ETD pseudospectral method is developed. The solution of nth IPE requires the computation of the input term that is obtained by differentiation of the solution of n - 1th IPE. The numerical noise resulting from such differentiation spoils the solutions of higher-order IPEs. It is shown that this noise can be suppressed via a filtering procedure involving Chebyshev polynomials of a discrete variable. In this study Pade type iterative parabolic approximations are introduced both for the case of linear and nonlinear media. It is shown that Pade-type approximations are more suitable for solving the problems of wave propagation. (c) 2021 Elsevier B.V. All rights reserved.
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